The mammalian heart has generally been considered to lack the ability to repair itself after injury, but a 2011 study in new-born mice challenged this view, providing evidence for complete regeneration after resection of 10% of the apex, the lowest part of the heart. In a study published by Cell Press in Stem Cell Reports on April 3, 2014, researchers attempted to replicate these recent findings but failed to uncover any evidence of complete heart regeneration in new-born mice that underwent apex resection.

"Our results question the usefulness of the apex resection model for identifying molecular mechanisms underlying heart regeneration after damage and underscore the need for the scientific community to firmly establish whether or not the mammalian heart is capable of regeneration," says lead study author Ditte Andersen of Odense University Hospital and the University of Southern Denmark.

The
apex is still missing in AR hearts and scar

formation
with connective tissue and fat is seen.

Credit: Stem Cell Reports, Andersen et al..

Cardiovascular disease is currently one of the leading causes of death worldwide, and scientists have mainly attributed this high mortality rate to the inability of the mammalian heart to regenerate after injury. Novel therapies capable of enhancing the heart's ability to recover after a heart attack or other type of injury are urgently needed. That's why a 2011 Science report from Porrello et al. that provided evidence of complete heart regeneration in new-born mice attracted a great deal of attention and raised hopes for identifying factors that could improve heart regeneration.

The AR
heart is more rounded and the apex is

lined by a scar composed of Collagen (red).

Credit: Stem Cell Reports, Andersen et al..

This study prompted Andersen, Søren Sheikh, and their colleagues to look for factors that enable heart regeneration, but they were surprised to find no signs of true heart regeneration in new-born mice that underwent apex resection. Three weeks after this procedure, the damaged hearts were about 10% shorter and weighed 14% less than the hearts of control mice that underwent the same surgical procedure without apex resection. Moreover, the damaged hearts had large scars and lacked proliferating muscle cells crucial for restoring heart function.

"The notion of mammalian heart regeneration has given a lot of hope in the scientific community for finding important factors that may be used for improving adult heart regeneration," Andersen says.

"We hope that our study will add another view on this important matter and spur a lot of studies from other independent labs that may shed further light on this controversial area of research."